CN101777855B

CN101777855B - Solar power plant

Info

Publication number: CN101777855B
Application number: CN201010002348.6A
Authority: CN
Inventors: 尤西·阿克贝格; 卡里·科瓦宁; 彼得·林德格伦
Original assignee: ABB AB
Current assignee: ABB Technology AG
Priority date: 2009-01-12
Filing date: 2010-01-11
Publication date: 2014-03-05
Anticipated expiration: 2030-01-11
Also published as: FI20095018A0; US20100180926A1; FI122046B; CN101777855A; EP2207248A2; US8704406B2; EP2207248B1; FI20095018A; EP2207248A3

Abstract

A solar power plant including a solar battery device is disclosed for converting solar energy into electric energy, and having a plurality of solar cell units, each solar cell unit containing a first cell pole and a second cell pole. The cell poles can cooperate for feeding electric energy produced by the solar cell unit as direct current out of the solar cell unit. A direct-current converter can include a plurality of direct-current input poles and two direct-current output poles, each direct-current input pole being connected to at least one cell pole. The direct-current converter can convert input direct currents entered via the direct-current input poles, and having input voltages, into an output direct current having an output voltage, and feed the output direct current via the direct-current output poles out of the direct-current converter. The direct-current converter can include a three-phase inverter unit having three phase poles and two direct-voltage poles, the inverter unit being adapted to serve as a direct-current converter in such a manner that each of the three phase poles are adapted as direct-current input poles and each of the direct-voltage poles is in electrically conductive connection to exactly one direct-current output pole of the direct-current converter.

Description

Solar power plant

Technical field

The present invention relates to according to the solar power plant of the preamble of claim 1.

Background technology

Understood by solar cell and converted the solar radiation of visible frequency to electric energy.Each solar cell all produces direct current, the solar radiation that its amplitude is subject to along with discussed solar cell and changing.Conventionally suitably provide the solar power plant that comprises a plurality of solar cells, the plurality of solar cell to have to be applicable to and convert the input dc power obtaining from solar cell and there is input voltage the galvanic direct current transducer device of output with output voltage to.Understood by realizing direct current transducer device with single-phase DC/DC chopper.

Utilize the problem of the direct current transducer device of the solar power plant that single-phase DC/DC chopper realizes be they cause expensive, need large quantity space and be not completely reliably.

Summary of the invention

One object of the present invention is to provide the solar power plant that can alleviate the problems referred to above.Object of the present invention is realized by the solar power plant described in independent claims 1 by its feature.The preferred embodiment of the present invention is open in appurtenance.

The present invention is based on three-phase inverter unit as the direct current transducer in the direct current transducer device of solar power plant.

According to the advantage of solar power plant of the present invention, comprise the lower cost of direct current transducer device, less space requirement and higher reliability.Owing to for example comparing three-phase inverter with the batch production of single-phase DC/DC chopper, manufactured in large quantity, therefore realized lower cost.Because six switches in three-phase inverter unit are integrated in a unit so the less space of needs.Due to three-phase inverter unit than single-phase DC/DC chopper, use more, make to there is more experience using on three-phase inverter unit, so higher than single-phase DC/DC chopper of the reliability of three-phase inverter.

Embodiment

Now, with reference to showing according to the accompanying drawing 1 of the simplification connection layout of the solar power plant of the embodiment of the present invention, illustrate in greater detail in conjunction with the preferred embodiments the present invention.

The solar power plant of Fig. 1 comprises solar battery apparatus 2, is applicable to solar energy to be converted to direct current; Direct current transducer device 4, the input dc power that is applicable to solar battery apparatus 2 to produce is converted to output direct current; Energy accumulating device, is applicable to store electrical energy; And network inverter device 8, the electric power being applicable to being fed to by direct current transducer device 4 carries out inversion and is fed to power distribution network.

Solar battery apparatus 2 comprises a plurality of solar battery cells 21 to 25, each solar battery cell includes the first battery electrode and the second battery electrode, is applicable to cooperate using the electric energy being produced by solar battery cell is fed to sunny energy battery unit as direct current.In Fig. 1, the first battery electrode of each solar battery cell 21 to 25 is positive electrodes and the second battery electrode is negative electrode, this means that the electromotive force of the first battery electrode is higher than the operating conditions of the electromotive force of the second battery electrode.

Direct current transducer device 4 comprises six direct current input electrodes, its each be all connected at least one battery electrode and two direct current output electrodes.Direct current transducer device 4 is applicable to convert the input dc power entering via direct current input electrode and have an input voltage output direct current with output voltage to, and this output direct current is fed to out to direct current transducer device 4 via direct current output electrode.

Direct current transducer device 4 is realized by two three-

phase inverter unit

11 and 12, and each three-phase inverter unit all has three phase electrodes and two direct voltage electrodes.The phase electrode of inverter unit 11 is by L1 ₁₁, L2 ₁₁, and L3 ₁₁represent, direct voltage electrode is by INV ₁₁+ and INV ₁₁-represent.The phase electrode of inverter unit 12 is successively by L1 ₁₂, L2 ₁₂and L3 ₁₂represent, direct voltage electrode is by INV ₁₂+ and INV ₁₂-represent.Each inverter unit is all applicable in the following manner as direct current transducer: each in its three phase electrodes is applicable to the direct current input electrode of direct current transducer device, and each in its direct voltage electrode is connected to a direct current output electrode of direct current transducer device 4 by conduction.Like this, direct current transducer device 4 just has a positive direct current output electrode and just has a negative direct current output electrode.

In alternative embodiment of the present invention, direct current transducer device only comprises an inverter unit.In the case, the direct voltage electrode of inverter unit is applicable to the direct current output electrode as direct current transducer device, in other words, the direct voltage electrode of inverter unit assembly can be as the direct current output electrode of direct current transducer device without any add-on assemble or connection.Connection about the direct current input electrode of direct current transducer device, whether obvious scope of the present invention comprises that the direct current being produced by solar battery apparatus is introduced in all solutions of inverter unit via phase electrode, and irrelevant by some add-on assembles with the direct current being introduced into.

Each phase electrode of inverter unit 11 is connected to just what a battery electrode in the following manner: phase electrode L1 ₁₁be connected to the first battery electrode DC of solar battery cell 21 ₂₁+, phase electrode L2 ₁₁be connected to the first battery electrode DC of solar battery cell 22 ₂₂+, and phase electrode L3 ₁₁be connected to the first battery electrode DC of solar battery cell 23 ₂₃+.For three phase electrodes of inverter unit 12, first-phase electrode L1 ₁₂be connected to the first battery electrode DC of solar battery cell 24 ₂₄+, second-phase electrode L2 ₁₂be connected to the second battery electrode DC of solar battery cell 24 ₂₄-and the first battery electrode DC of solar battery cell 25 ₂₅+, and third phase electrode L3 ₁₂be connected to the second battery electrode DC of solar battery cell 25 ₂₅-.

Inverter unit

11 and 12 is connected in parallel in the following manner: the positive direct-current voltages electrode INV of inverter unit 11 ₁₁+ and the positive direct-current voltages electrode INV of inverter unit 12 ₁₂+ conduction is connected to the positive direct-current output electrode of direct current transducer device 4.Correspondingly, the negative dc voltage electrode INV of inverter unit 11 ₁₁-and the negative dc voltage electrode INV of inverter unit 12 ₁₂-conduction is connected to the negative direct current output electrode of direct current transducer device 4.

According in the direct current transducer device of solar power plant of the present invention, inverter unit is applicable to deviate from common mode and works.Conventionally, inverter unit is applicable in the following manner direct current be carried out to inversion: the direct current that is incorporated into the direct voltage electrode of inverter unit is converted into alternating current in inverter unit, and this alternating current is seen off via the phase feedthrough electrode of inverter unit.In this article, the common operation (that is, inversion) of the electrode of inverter unit based on inverter unit named.For this reason, the electrode of each inverter unit of direct current transducer device is applicable to receive the direct current from solar battery apparatus, and it is known as phase electrode.

Energy accumulating device is connected to the direct current output electrode of direct current transducer device 4 and is applicable to store electrical energy.Energy accumulating device comprises the direct voltage electrode INV that is connected to inverter unit 11 ₁₁+ and INV ₁₁-between capacitor C ₁₁, be connected to the direct voltage electrode INV of inverter unit 12 ₁₂+ and INV ₁₂-between capacitor C ₁₂, and be connected to the capacitor C between the direct voltage electrode of network inverter device 8 ₈.Energy accumulating device is applicable to make the time in the electric power production process of solar battery apparatus 2 to change planarization.

Network inverter device 8 comprises three-phase inverter unit 13, its positive direct-current voltages electrode INV ₁₃+ conduction is connected to the positive direct-current voltages electrode INV of

inverter unit

11 and 12 ₁₁+ and INV ₁₂+.The negative dc voltage electrode INV of inverter 13 ₁₃-conduction is connected to the negative dc voltage electrode INV of inverter unit 11 and 12 ₁₁-and INV ₁₂-.

The three-phase inverter unit 13 of network inverter device 8 can be identical with the

inverter unit

11 and 12 of direct current transducer device 4.In an embodiment of the present invention, all three-phase inverters unit for direct current transducer device and network inverter device is identical.The advantage of this configuration for example comprises and therefore contributes to safeguard owing to having reduced the quantity of spare part.

Each in

inverter unit

11,12 and 13 includes six gate-controlled switches, and in the mode understood completely in the art, the mode with bridge joint connects for they.Bridge joint comprises positive bus-bar and negative busbar.Positive bus-bar has substantially identical with the positive direct-current voltages electrode of inverter unit electromotive force under mode of operation, and negative busbar has substantially identical with the negative dc voltage electrode of inverter unit electromotive force under mode of operation.As can be seen from Figure 1, the positive bus-bar of each inverter unit is connected to three gate-controlled switches and negative busbar is connected to three gate-controlled switches lower row upper row.From Fig. 1, further find out

solar battery cell

21,22 and the second battery electrode DC of 23 ₂₁-, DC ₂₂-and DC ₂₃-, i.e. negative battery electrode, conduction is connected to the negative busbar of inverter unit 11 in the following manner:

solar battery cell

21,22 has substantially identical with the negative busbar of inverter unit 11 electromotive force with the second battery electrode of 23 under operating conditions.

The gate-controlled switch of each inverter unit is controlled by the control unit of the inverter unit that comes into question.Control unit CU ₁₁be applicable to the gate-controlled switch of control inverter unit 11, control unit CU ₁₂be applicable to the gate-controlled switch of control inverter unit 12, and control unit CU ₁₃be applicable to the gate-controlled switch of control inverter 13.

Control unit CU ₁₁be applicable to measure amplitude and the voltage of the electric current of each the phase electrode enter inverter unit 11.In other words, control unit CU ₁₁measurement enters phase electrode L1 ₁₁the amplitude I1 of electric current ₁₁with voltage U 1 ₁₁, enter phase electrode L2 ₁₁the amplitude I2 of electric current ₁₁with voltage U 2 ₁₁, enter phase electrode L3 ₁₁the amplitude I3 of electric current ₁₁with voltage U 3 ₁₁.In addition control unit CU, ₁₁be applicable to measure the negative busbar of inverter unit 11 and the electric current I between

solar battery cell

21,22 and the second battery electrode of 23 _rand the voltage U of the negative busbar of inverter unit 11 _r.

Control unit CU ₁₂be applicable to measure the voltage and current of each phase electrode of inverter unit 12.By the variable of measurement, be phase electrode L1 ₁₂voltage U 1 ₁₂with electric current I 1 ₁₂, phase electrode L2 ₁₂voltage U 2 ₁₂with electric current I 2 ₁₂, and phase electrode L3 ₁₂voltage U 3 ₁₂with electric current I 3 ₁₂.

Each solar battery cell 21 to 25 comprises a plurality of solar cell strings that are connected in parallel, and each solar cell string comprises a plurality of solar cell devices that are connected in series.In alternative embodiment of the present invention, solar battery apparatus comprises that at least one only includes the solar battery cell of a solar cell string.In another alternative embodiment of the present invention, solar battery apparatus comprises at least one solar battery cell, and solar cell devices all in this solar battery cell are connected in parallel with each other.In addition,, in another alternative embodiment of the present invention, solar battery apparatus comprises having just at least one solar battery cell of what a solar cell device.The various combinations of above embodiment are also feasible.

In solar power plant according to the present invention, the power of each solar battery cell can be by utilizing the metrical information of corresponding control unit and carrying out independent optimization by control the gate-controlled switch of direct current transducer device based on this metrical information.Utilize direct current input electrode special measurement information can also carry out the special-purpose monitoring of solar battery cell and protection.

According to the embodiment of the present invention, there is the solar battery cell of the electrology characteristic (for example, about rated power or rated voltage) differing from one another, can be connected to the inverter unit of the direct current transducer device of solar power plant.For example, in the situation that the voltage being generated by solar battery cell of a direct current input electrode that is connected to direct current transducer device lower than the voltage of other direct current input electrode, be connected to the direct current input electrode with low voltage gate-controlled switch so that the mode that they rise to the level substantially the same with other direct current input electrode by voltage control.

Obviously for those skilled in the art, basic thought of the present invention can be realized in many ways.Therefore, the present invention and embodiment are not limited to described example but can change within the scope of the claims.

Claims

1. a solar power plant, comprising:

Solar battery apparatus (2), is applicable to convert solar energy to electric energy and comprise a plurality of solar battery cells (21 to 25), and each solar battery cell (21) includes the first battery electrode (DC ₂₁+) and the second battery electrode (DC ₂₁-), these battery electrodes (DC ₂₁+, DC ₂₁-) be applicable to coordinate the electric energy of usining being produced by solar battery cell (21) to be fed to out described solar battery cell (21) as direct current; And

Direct current transducer device (4), comprises a plurality of direct current input electrodes and two direct current output electrodes, and each direct current input electrode is all connected at least one battery electrode (DC ₂₁+), and described direct current transducer device (4) is applicable to convert the input dc power entering via described direct current input electrode and have an input voltage output direct current with output voltage to, and described output direct current is fed to out to described direct current transducer device (4) via described direct current output electrode

Described solar power plant is characterised in that: described direct current transducer device (4) comprises having three phase electrode (L1 ₁₁, L2 ₁₁, L3 ₁₁; L1 ₁₂, L2 ₁₂, L3 ₁₂) and two direct voltage electrode (INV ₁₁+, INV ₁₁-; INV ₁₂+, INV ₁₂-) three-phase inverter unit (11; 12), described inverter unit (11; 12) be applicable to come in the following manner as direct current transducer, described mode is described three phase electrode (L1 ₁₁, L2 ₁₁, L3 ₁₁; L1 ₁₂, L2 ₁₂, L3 ₁₂) in each be applicable to as direct current input electrode and described direct voltage electrode (INV ₁₁+, INV ₁₁-; INV ₁₂+, INV ₁₂-) in each conduction be connected to proper what a direct current output electrode of described direct current transducer device.

2. solar power plant according to claim 1, is characterized in that, each phase electrode (L1 of the described inverter unit (11) of described direct current transducer device ₁₁, L2 ₁₁, L3 ₁₁) be connected to just what a battery electrode (DC ₂₁+, DC ₂₂+, DC ₂₃+).

3. solar power plant according to claim 1, is characterized in that, described three phase electrode (L1 of the described inverter unit (12) of described direct current transducer device ₁₂, L2 ₁₂, L3 ₁₂) first-phase electrode (L1 ₁₂) be connected to the first battery electrode (DC of a solar battery cell (24) ₂₄+), second-phase electrode (L2 ₁₂) be connected to the second battery electrode (DC of a described solar battery cell (24) ₂₄-) and the first battery electrode (DC of the second solar battery cell (25) ₂₅+), and third phase electrode (L3 ₁₂) be connected to the second battery electrode (DC of described the second solar battery cell (25) ₂₅-).

4. according to the solar power plant of any one of aforementioned claim, it is characterized in that, described direct current transducer device (4) comprises at least two three-phase inverter unit (11; 12), the direct voltage electrode (INV of described three-phase inverter unit ₁₁+, INV ₁₁-; INV ₁₂+, INV ₁₂-) be connected in parallel.

5. according to the solar power plant of claim 1, it is characterized in that, also comprise the described direct current output electrode that is connected to described direct current transducer device (4) the energy accumulating device (C that is applicable to store electrical energy ₁₁, C ₁₂, C ₈).

6. according to the solar power plant of claim 1, it is characterized in that, also comprise and be applicable to the network inverter device (8) that the electricity that is fed to described direct current output electrode by described direct current transducer device (4) is reverse into three-phase alternating current and described three-phase alternating current is fed to power distribution network.

7. solar power plant according to claim 6, is characterized in that, described network inverter device (8) comprises the described three-phase inverter unit (11 with described direct current transducer device (4); 12) identical three-phase inverter unit (13).

8. according to the solar power plant of claim 1, it is characterized in that, at least one solar battery cell comprises a plurality of solar cell devices that are connected in series and/or a plurality of solar cell devices that are connected in parallel.

9. according to the solar power plant of claim 1, it is characterized in that, also comprise control unit (CU ₁₁), be applicable to measure each phase electrode (L1 of the described three-phase inverter unit (11) of described direct current transducer device ₁₁, L2 ₁₁, L3 ₁₁) voltage (U1 ₁₁, U2 ₁₁, U3 ₁₁) and electric current (I1 ₁₁, I2 ₁₁, I3 ₁₁), and the voltage and current based on measured is controlled the operation of above-mentioned three-phase inverter unit (11).